JPWO2012131894A1 - Power supply system, vehicle equipped with the same, and control method of power supply system - Google Patents

Abstract

The power supply system includes a power storage device (110) and an ECU (300), and supplies driving power to the load device (190). The power storage device (110) includes a shut-off device (CID) configured to operate when the internal pressure of the power storage device (110) exceeds a specified value and to shut off the energization path of the power storage device (110). The load device (190) includes a voltage sensor (180, 185) for detecting a voltage applied to the load device (190), and in response to the failure of the voltage sensor (180, 185), The supply of power from the device (190) to the power storage device (110) is stopped. When the voltage sensor (180, 185) fails, the ECU (300) is based on the change length of the actual current input to and output from the power storage device (110) during a predetermined period and the user operation. Based on the change length of the command current determined from the required power required, it is determined whether or not the shut-off device (CID) is activated.

Description

  The present invention relates to a power supply system, a vehicle on which the power supply system is mounted, and a method for controlling the power supply system, and more specifically, a technique for detecting the operation of a current interrupt device (CID) included in a power storage device. About.

  2. Description of the Related Art In recent years, attention has been paid to a vehicle that is mounted with a power storage device (for example, a secondary battery or a capacitor) and travels using driving force generated from electric power stored in the power storage device as an environment-friendly vehicle. Examples of the vehicle include an electric vehicle, a hybrid vehicle, and a fuel cell vehicle.

  Such a power storage device is generally configured to output a desired voltage by stacking a plurality of battery cells in series or in parallel. In these battery cells, when abnormality such as disconnection or short circuit occurs, the function of the power storage device may not be normally performed. Therefore, it is necessary to detect abnormality of the battery cell.

  Japanese Patent Laying-Open No. 2009-189209 (Patent Document 1) discloses that in a power supply device for a vehicle, a connection portion provided between a power storage device and an electric load load is set in a connected state in response to a vehicle activation instruction. A configuration is disclosed for diagnosing the presence or absence of a disconnection in the operating current supply path from the power storage device to the electric load based on the output of the current sensor when power is consumed by the load.

JP 2009-189209 A JP 2009-278705 A JP 2009-148139 A JP 2009-171644 A JP 2010-051072 A

  Some power storage devices include a current interrupt device (hereinafter also referred to as CID “Current Interrupt Device”) in each battery cell. This CID generally has a configuration in which, when an abnormality occurs in a battery cell and the internal pressure of the battery cell exceeds a specified value, the CID is activated by the internal pressure to cut off the energization path of the power storage device in hardware. Therefore, the overvoltage of the power storage device is prevented by operating the CID.

  However, it may not be possible to directly detect whether or not the CID is activated. For example, in a hybrid vehicle or the like, if the vehicle continues to run while the CID is activated, a large voltage is applied to the CID and the battery cell is operated. May cause secondary sparks, etc. Therefore, it is necessary to quickly detect that the CID has been operated.

  In Japanese Patent Application Laid-Open No. 2009-189209 (Patent Document 1) and the other patent documents described above, this CID is not described, and nothing is shown about the CID operation detection method.

  The present invention has been made to solve such a problem, and an object thereof is to accurately detect the operation of a CID in a power supply system including a power storage device including the CID.

  A power supply system according to the present invention includes a power storage device and a control device, and supplies driving power to a load device. The power storage device includes a shut-off device that is configured to operate when the internal pressure of the power storage device exceeds a specified value and to shut off the energization path of the power storage device. The load device includes a voltage detection unit for detecting a voltage applied to the load device, and in response to the failure of the voltage detection unit, the supply of power from the load device to the power storage device is stopped. A control apparatus detects the presence or absence of the action | operation of a cutoff device based on the information from the signal output part different from a voltage detection part.

  Preferably, the signal output unit includes a current detection unit for detecting an actual current input to and output from the power storage device. The control device detects whether or not the shut-off device is activated based on the actual current detected by the current detection unit and the command current to be input / output from the power storage device determined from the required power based on the user operation.

  Preferably, the control device sets a change length obtained by integrating a change amount for each sampling cycle for the actual current and a change amount for each sampling cycle for the command current during a predetermined period. Calculate the accumulated change length. And a control apparatus determines the presence or absence of the action | operation of a cutoff device based on the change length of the said actual current, and the change length of command current.

  Preferably, the control device uses the first threshold value and the second threshold value larger than the first threshold value, so that the change length of the actual current is smaller than the first threshold value, and When the change length of the command current is greater than the second threshold value, it is determined that the interrupting device has been activated.

  Preferably, a switching device for switching between conduction and non-conduction between the power storage device and the load device is provided in a path connecting the power storage device and the load device. The control device switches the switching device to non-conduction when it is determined that the shut-off device is activated.

  Preferably, the signal output unit includes an auxiliary device connected to the power storage device in parallel with the load device. The auxiliary device has a device capable of outputting a voltage drop signal indicating that the input voltage has dropped in a state where driving is required. A control apparatus detects the presence or absence of the action | operation of a cutoff device based on the voltage drop signal from an apparatus.

  Preferably, the device includes a voltage conversion device configured to step down power from the power storage device.

  Preferably, a switching device for switching between conduction and non-conduction between the power storage device and the load device is provided in a path connecting the power storage device and the load device. The control device switches the switching device to non-conduction when it is determined that the shut-off device is activated.

  A vehicle according to the present invention includes a power storage device, a load device including a drive device configured to generate a driving force of the vehicle using electric power from the power storage device, and a control device. The power storage device includes a shut-off device that is configured to operate when the internal pressure of the power storage device exceeds a specified value and to shut off the energization path of the power storage device. The load device includes a voltage detection unit for detecting a voltage applied to the load device, and in response to the failure of the voltage detection unit, the supply of power from the load device to the power storage device is stopped. A control apparatus detects the presence or absence of the action | operation of a cutoff device based on the information from the signal output part different from a voltage detection part.

  Preferably, the signal output unit includes a current detection unit for detecting an actual current input to and output from the power storage device. The control device stores power determined by a change length obtained by integrating a magnitude of a change amount for each sampling period with respect to an actual current detected by a current detection unit and a required power based on a user operation during a predetermined period. Calculates the change length of the amount of change for each sampling period for the command current to be input and output from the device, and whether or not the breaker operates based on the change length of the actual current and the change length of the command current Determine.

  Preferably, the signal output unit includes an auxiliary device connected to the power storage device in parallel with the load device. The auxiliary device has a voltage conversion device capable of stepping down the electric power from the power storage device and outputting a voltage drop signal indicating that the input voltage has dropped in a state where driving is required. A control apparatus detects the presence or absence of the action | operation of a cutoff device based on the voltage drop signal from a voltage converter.

  The control method of the power supply system by this invention is a control method about the power supply system containing the electrical storage apparatus for supplying drive electric power to a load apparatus. The power storage device includes a shut-off device that is configured to operate when the internal pressure of the power storage device exceeds a specified value and to shut off the energization path of the power storage device. The load device includes a voltage detection unit for detecting a voltage applied to the load device. The control method includes detecting a failure of the voltage detection unit, stopping supplying power from the load device to the power storage device in response to the failure of the voltage detection unit, and the voltage detection unit. Detecting whether or not the shut-off device is activated based on information from different signal output units.

  Preferably, the signal output unit includes a current detection unit for detecting an actual current input to and output from the power storage device. The step of detecting the presence or absence of the operation of the interrupting device is a step of calculating a change length obtained by integrating the magnitude of the change amount for each sampling period for the actual current detected by the current detection unit during a predetermined period. And a step of calculating a change length obtained by integrating a magnitude of a change amount for each sampling period with respect to a command current to be input / output from a power storage device determined from a required power based on a user operation during a predetermined period; Determining whether or not the interrupting device is activated based on the change length of the actual current and the change length of the command current.

  Preferably, the signal output unit includes an auxiliary device connected to the power storage device in parallel with the load device. The auxiliary device includes a voltage conversion device capable of stepping down the electric power from the power storage device and outputting a voltage drop signal indicating that the input voltage has dropped in a state where driving is required. The step of detecting the presence / absence of the operation of the shut-off device includes the step of detecting the presence / absence of the operation of the shut-off device based on the voltage drop signal from the voltage conversion device.

  ADVANTAGE OF THE INVENTION According to this invention, the action | operation of CID can be detected accurately in the power supply system provided with the electrical storage apparatus containing CID.

1 is an overall block diagram of a vehicle equipped with a power supply system according to an embodiment of the present invention. It is a figure which shows the detailed structure of an electrical storage apparatus. It is a figure for demonstrating electric current change length. It is a figure for demonstrating the relationship between an actual electric current change length and command electric current change length, and a vehicle state. 3 is a time chart for explaining an outline of CID operation detection control in the first embodiment. In Embodiment 1, it is a functional block diagram for demonstrating the operation | movement detection control of CID performed by ECU. 5 is a flowchart for illustrating details of a CID operation detection control process executed by an ECU in the first embodiment. In Embodiment 2, it is a flowchart for demonstrating the detail of the action | operation detection control process of CID performed by ECU. In Embodiment 3, it is a flowchart for demonstrating the detail of the action | operation detection control process of CID performed by ECU.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals and description thereof will not be repeated.

[Basic configuration of vehicle]
FIG. 1 is an overall block diagram of a vehicle 100 including a power supply system according to the present embodiment.

  Referring to FIG. 1, vehicle 100 includes a power storage device 110, a system main relay SMR 115, a load device 190, an auxiliary device 200, and an ECU (Electronic Control Unit) 300 that is a control device.

  The load device 190 includes a converter 120, inverters 130 and 135, motor generators 140 and 145, a power transmission gear 150, an engine 160, driving wheels 170, voltage sensors 180 and 185 as voltage detection units, and capacitors. Including C1 and C2.

  The power storage device 110 is a power storage element configured to be chargeable / dischargeable. The power storage device 110 includes, for example, a secondary battery such as a lithium ion battery, a nickel metal hydride battery, or a lead storage battery, and a power storage element such as an electric double layer capacitor.

  Power storage device 110 is connected to converter 120 via power line PL1 and ground line NL1. Power storage device 110 stores the electric power generated by motor generators 140 and 145. The output of power storage device 110 is, for example, about 200V.

  The power storage device 110 is provided with a voltage sensor 111 and a current sensor 112. Voltage sensor 111 detects the voltage of power storage device 110 and outputs the detected value VB to ECU 300. Current sensor 112 detects a current input / output to / from power storage device 110 and outputs a detected value IB to ECU 300. 1 shows a configuration in which current sensor 112 is provided on power line PL1 connected to the positive terminal of power storage device 110, but is provided on ground line NL1 connected to the negative terminal of power storage device 110. It may be a configuration.

  Relays included in SMR 115 are respectively inserted in power line PL1 and ground line NL1 connecting power storage device 110 and converter 120. SMR 115 is controlled by control signal SE <b> 1 from ECU 300, and switches between power supply and cutoff between power storage device 110 and load device 190.

  Capacitor C1 is connected between power line PL1 and ground line NL1. Capacitor C1 reduces voltage fluctuation between power line PL1 and ground line NL1. Voltage sensor 180 detects voltage VL applied to capacitor C1 and outputs the detected value to ECU 300.

  Converter 120 includes switching elements Q1, Q2, diodes D1, D2, and a reactor L1.

  Switching elements Q1 and Q2 are connected in series between power line PL2 and ground line NL1, with the direction from power line PL2 toward ground line NL1 as the forward direction. In this embodiment, an IGBT (Insulated Gate Bipolar Transistor), a power MOS (Metal Oxide Semiconductor) transistor, a power bipolar transistor, or the like can be used as the switching element.

  Antiparallel diodes D1 and D2 are connected to switching elements Q1 and Q2, respectively. Reactor L1 is provided between a connection node of switching elements Q1 and Q2 and power line PL1.

  Switching elements Q1, Q2 are controlled by a control signal PWC from ECU 300, and perform a voltage conversion operation between power line PL1 and ground line NL1, and power line PL2 and ground line NL1.

  Converter 120 is basically controlled such that switching elements Q1 and Q2 are turned on and off in a complementary manner in each switching period. Converter 120 boosts DC voltage VL to DC voltage VH during the boosting operation. This boosting operation is performed by supplying the electromagnetic energy accumulated in reactor L1 during the ON period of switching element Q2 to power line PL2 via switching element Q1 and antiparallel diode D1.

  Converter 120 steps down DC voltage VH to DC voltage VL during the step-down operation. This step-down operation is performed by supplying the electromagnetic energy stored in reactor L1 during the ON period of switching element Q1 to ground line NL1 via switching element Q2 and antiparallel diode D2.

  The voltage conversion ratio (the ratio of VH and VL) in these step-up and step-down operations is controlled by the on-period ratio (duty ratio) of the switching elements Q1 and Q2 in the switching period. When the step-up operation and the step-down operation are not required (that is, VH = VL), the voltage conversion ratio = 1 by setting the control signal PWC to fix the switching elements Q1 and Q2 to ON and OFF, respectively. 0.0 (duty ratio = 100%).

  Capacitor C2 is connected between power line PL2 connecting converter 120 and inverters 130 and 135 and ground line NL1. Capacitor C2 reduces voltage fluctuation between power line PL2 and ground line NL1. Voltage sensor 185 detects voltage VH applied to capacitor C2, and outputs the detected value to ECU 300.

  Inverters 130 and 135 are connected in parallel to converter 120 via power line PL2 and ground line NL1. Inverters 130 and 135 are controlled by control commands PWI1 and PWI2 from ECU 300, respectively, and convert DC power output from converter 120 into AC power for driving motor generators 140 and 145, respectively.

  Motor generators 140 and 145 are AC rotating electric machines, for example, permanent magnet type synchronous motors having a rotor in which permanent magnets are embedded.

  The output torques of motor generators 140 and 145 are transmitted to drive wheels 170 via power transmission gear 150 constituted by a speed reducer and a power split mechanism, thereby causing vehicle 100 to travel. Motor generators 140 and 145 can generate electric power with the rotational force of drive wheels 170 during regenerative braking operation of vehicle 100. The generated power is converted into charging power for power storage device 110 by inverters 130 and 135.

  Auxiliary device 200 includes a DC / DC converter 210, an auxiliary load 220, and an auxiliary battery 230.

  DC / DC converter 210 is connected in parallel with load device 190 to power line PL1 and ground line NL1. DC / DC converter 210 steps down electric power generated by power storage device 110 or motor generators 140 and 145 based on control signal PWD from ECU 300, and supplies power to auxiliary load 220 and auxiliary battery 230 via power line PL3. Supply stepped down power.

  When DC / DC converter 210 receives control signal PWD from ECU 300 and detects that the input voltage from power line PL1 and ground line NL1 has dropped below a predetermined voltage level, DC / DC converter 210 sends low voltage signal UV to ECU 300. Is output.

  Auxiliary battery 230 is typically formed of a lead storage battery. Auxiliary battery 230 supplies power supply voltage to low-voltage loads of vehicle 100 such as auxiliary load 220 and ECU 300. Auxiliary battery 230 is charged with electric power supplied from DC / DC converter 210. The output voltage of auxiliary battery 230 is lower than the output voltage of power storage device 110, for example, about 12V.

  The auxiliary machine load 220 includes devices such as lamps, wipers, heaters, audio, and navigation systems.

  ECU 300 includes a CPU (Central Processing Unit), a storage device, and an input / output buffer, all of which are not shown in FIG. 1, and inputs signals from each sensor and the like, and outputs control signals to each device. 100 and each device are controlled. Note that these controls are not limited to processing by software, and can be processed by dedicated hardware (electronic circuit).

  ECU 300 receives detected values of voltage VB and current IB from a sensor (not shown) included in power storage device 110. ECU 300 calculates the state of charge of power storage device 110 (hereinafter also referred to as SOC (State of Charge)) based on voltage VB and current IB.

  The power storage device 110 is configured to output a desired voltage by connecting a plurality of battery cells in series, as will be described later with reference to FIG. 2, but the voltage VB detected by the voltage sensor 111 is In general, the calculation is based on the sum of the voltages of the individual battery cells, not the voltage across the power storage device 110. Therefore, the output of the voltage VB does not necessarily become zero even when the CID is activated.

  ECU 300 also receives required power PR to be input / output from power storage device 110, out of vehicle driving force determined based on an operation of an accelerator pedal (not shown) by a user. ECU 300 controls converter 120 and inverters 130 and 135 based on this required power PR.

  In FIG. 1, one control device is provided as the ECU 300. However, for example, for each function or control target device, such as a control device for the load device 190 or a control device for the power storage device 110. It is good also as a structure which provides a separate control apparatus.

  FIG. 2 is a diagram showing a detailed configuration of power storage device 110. Referring to FIG. 2, power storage device 110 is configured to include a plurality of battery cells CL1 to CLn (hereinafter also collectively referred to as CL) connected in series, and a desired output depending on the number of battery cells CL. A voltage is obtained. Each battery cell CL is provided with a current interrupt device CID.

  When the internal pressure of the battery cell CL exceeds a specified value due to the gas generated from the electrolyte of the battery cell CL, the CID is activated by the internal pressure and physically shuts off the battery cell from other battery cells. . Therefore, when any CID of battery cell CL is activated, no current flows through power storage device 110.

  When the CID is activated and the current is interrupted, a difference voltage between the total voltage of the battery cells other than the battery cell in which the CID is activated and the input voltage VL to the load device 190 may be applied to the activated CID. Are known. Therefore, in a state where the SMR 115 is in a conductive state, for example, when the charge of the capacitor C1 decreases due to power consumption by the load device 190 or the auxiliary device 200 and the voltage VL decreases, the voltage applied to the activated CID increases accordingly. . Since the gap between the portions cut off by the CID is small, if the voltage applied to the CID exceeds a predetermined withstand voltage, a secondary failure is induced, for example, a spark is generated in the gap. There is a fear. Therefore, it is necessary to quickly detect the operation of the CID. However, in general, the battery cell CL may not have a means for outputting that the CID is activated.

  Further, it is known from experiments that the voltage VL fluctuates when the CID is activated. This is because charging / discharging between the power storage device 110 and the load device 190 is interrupted, so that the amount of charge stored in the capacitor C1 varies depending on power consumption or power generation by the load device 190 and power consumption by the auxiliary device 200. Because.

  For example, when the CID operates at a high load when the vehicle 100 is traveling and the power consumption by the PCU 120 is large, the voltage VL decreases rapidly compared to the case where the CID is not operating. For this reason, when the load is high, it is possible to detect whether or not the CID is activated by monitoring the degree of increase or decrease of the voltage VL. Alternatively, it is also possible to detect whether or not the CID is activated by using the voltage VH instead of the voltage VL.

[Embodiment 1]
In the vehicle having the above-described configuration, when voltage sensors 180 and 185 (hereinafter collectively referred to as “system voltage sensors”) fail, the voltages on the low voltage side and high voltage side of converter 120 are reduced. Since the ECU 300 cannot recognize the voltage, the converter 120 cannot perform an appropriate voltage conversion operation.

  In such a case, for example, the gates of switching elements Q1 and Q2 of converter 120 are shut off to stop the voltage conversion operation and prohibit charging of power storage device 110, while only discharging from power storage device 110 is performed. Permit to continue the vehicle. In this case, control using input / output current IB from power storage device 110 is often performed instead of system voltage sensor.

  In such a state, when the CID is activated, the input / output current IB from the power storage device 110 is substantially zero. However, current IB may be zero even when, for example, there is no power consumption by load device 190 and auxiliary device 200, or when power generation and power consumption are balanced in motor generators 140 and 145. is there. Therefore, it may occur that the operation of the CID cannot be properly detected by monitoring the behavior of the current IB.

  In view of such a problem, in the first embodiment, when the system voltage sensor becomes abnormal, an actual input / output current IB (hereinafter also referred to as “actual current IB”) of power storage device 110 and power storage. A configuration for detecting the operation of the CID without using the detection value of the system voltage sensor based on the requested current to be input / output from the device 110 (hereinafter also referred to as “command current IR”) will be described. Specifically, the presence / absence of CID operation is detected based on a “change length” obtained by integrating changes in the magnitudes of the actual current IB and the command current IR for each sampling period in a predetermined period. By doing so, it is possible to suppress erroneous detection of the operation of the CID and detect that the CID has operated with high accuracy.

  Here, the actual current change length IBint and the command current change length IRint will be described first with reference to FIG. 3. In FIG. 3, the actual current change length IBint will be described as an example.

  Referring to FIG. 3, a case where current IB input / output to / from power storage device 110 changes as shown by curve W10 in FIG. ECU 300 samples input / output current IB to the power storage device at a constant cycle. It is assumed that the current value at each sampling is indicated by each point on the curve W10. For example, the current values at time t = i−1, i from the start of sampling are expressed as IB (i−1) and IB (i, respectively. ).

  Then, the current change amount ΔIB (i) from the time t = i−1 to the time t = i is expressed as the following formula (1).

ΔIB (i) = | IB (i) −IB (i−1) | (1)
At this time, assuming that the number of samplings in a predetermined period T0 is k, the actual current change length IBint (k) is expressed as in Expression (2).

IBint (k) = Σ | IB (i) −IB (i−1) | (2)
(I = 1, k)
That is, the actual current change length IBint can be an index representing how much the actual current IB has changed in a predetermined period T0. Therefore, for example, even if the average value of the actual current IB during the period T0 is the same, the value of the actual current change length IBint is larger when the current is oscillating during that period.

Next, a method for determining the operation of the CID using the actual current change length IBint and the command current change length IPint will be described with reference to FIG. In FIG. 4, the horizontal axis represents the command current change length IRint, and the vertical axis represents the actual current change length IBint.

  Referring to FIGS. 1 and 4, when CID is not operating and power storage device 110 is normal, command current IR and actual current IB are generally equal in consideration of a time delay such as a control delay. Value. Therefore, the actual current change length IBint and the command current change length IRint are plotted in the range of the region A surrounded by the dotted line in FIG.

  On the other hand, when the CID operates, no current is input / output from the power storage device 110, so the command current change length IRint increases with time, but the actual current change length IBint becomes almost zero.

  That is, the command current change length IRint is equal to or greater than the threshold value α (α> 0) and the actual current change length IBint is a threshold value while taking into consideration the detection error of the current sensor 112 and the calculation error of the command current IR. By detecting that the region is smaller than the value β (0 ≦ β <α) (that is, the region B in FIG. 4), it can be determined that the CID is activated.

  FIG. 5 is a time chart for explaining the outline of the CID operation detection control in the first embodiment. In FIG. 5, the horizontal axis indicates time, and the vertical axis indicates the actual current change length IBint (lower stage), the command current change length IRint (middle stage), and the counter CNT (upper stage) indicating the accumulated time of each change length. Is shown.

  Referring to FIG. 5, until time t1, at least one of voltage sensors 180 and 185 as system voltage sensors is normal, and CID operation monitoring is performed based on the sensors, and actual current change length IBint and The integration process of the command current change length IRint is not performed, and the counter CNT also remains zero.

  When both system voltage sensors become abnormal at time t1, the gates of switching elements Q1 and Q2 of converter 120 are cut off, and integration processing of actual current change length IBint and command current change length IRint is started.

  Since gates of switching elements Q1, Q2 of converter 120 are cut off and only discharging of power storage device 110 can be performed, both actual current IB and command current IR are positive values.

  When the counter CNT reaches a threshold value γ indicating a predetermined reference time for determining the operation of the CID (time t2), the values of the command current change length IRint and the actual current change length IBint at that time are Are compared with the above-mentioned threshold values α and β, respectively.

  At time t2, since IRint> α and IBint> β and are outside the range of the region B described in FIG. 4, it is determined that the CID is not operating. After the determination is completed, the command current change length IRint, the actual current change length IBint, and the counter CNT are reset to initial values.

  At the determination timings at times t3 and t4, as in the case of time t2, it is determined that the CID is not operating.

  If the CID is activated at time t5 while the integration process is being performed again from time t4, the command current change length IRint continuously increases with time. On the other hand, with respect to actual current change length IBint, no current is output from power storage device 110 due to the operation of CID, so that the value is maintained from time t5 to time t6, which is the next determination timing.

  In the example of FIG. 5, at the determination timing at time t6, although the CID is operating, both the command current change length IRint and the actual current change length IBint are larger than the threshold value. Therefore, the operation of the CID is not detected yet at time t6.

  However, after each integrated value is reset to the initial value at time t6, the command current change length IRint increases with time, but the actual current change length IBint remains the initial value.

  Then, at time t7, which is the next determination timing, IRint> α and IBint <β, which is the range of region B in FIG. Thus, it is determined that the CID has been activated. In response, the SMR 115 is blocked.

  FIG. 6 is a functional block diagram for explaining the CID operation detection control executed by ECU 300 in the first embodiment. Each functional block described in the functional block diagram of FIG. 6 is realized by hardware or software processing by ECU 300.

  Referring to FIG. 6, ECU 300 includes a current detection unit 310, a command current calculation unit 320, an integration unit 330, a determination unit 340, a relay control unit 350, and a drive control unit 360.

  Current detection unit 310 receives actual current IB input to and output from power storage device 110 detected by current sensor 112. The current detection unit 310 calculates a change amount ΔIB of the current IB from the current value detected in the previous sampling cycle. Current detection unit 310 then outputs change amount ΔIB of actual current IB to integration unit 330.

  Command current calculation unit 320 receives required power PR to be input / output from power storage device 110 and voltage VB of power storage device 110 detected by voltage sensor 111. Based on these pieces of information, command current calculation unit 320 calculates command current IR to be input / output from power storage device 110. Specifically, the command current IR is calculated by IR = PR / VB.

  The command current calculation unit 320 also calculates a change amount ΔIR from the command current calculated in the previous sampling cycle. Then, command current calculation unit 320 outputs change amount ΔIR of command current IR to integration unit 330.

  Accumulation unit 330 receives change amount ΔIB of actual current IB from current detection unit 310 and change amount ΔIR of the command current from command current calculation unit 320. Accumulator 330 receives control signal SE1 for driving SMR 115 and an abnormal signal ABN indicating that the system voltage sensor is abnormal.

  Accumulator 330 changes change amount ΔIB of actual current IB and change in command current IR for each sampling period when SMR 115 is in a conductive state by control signal SE1 and abnormal signal ABN indicates an abnormality of the system voltage sensor. The amount ΔIR is integrated to calculate the actual current change length IBint and the command current change length IRint. Further, the integrating unit 330 also integrates the counter CNT that represents the time (monitoring time) during which the integration is executed.

  Accumulation unit 330 then outputs the calculated actual current change length IBint, command current change length IRint, and counter CNT to determination unit 340. When the counter CNT reaches a count value corresponding to a predetermined reference time and the output to the determination unit 340 is completed, the integrating unit 330 completes the actual current change length IBint, the command current change length IRint, and the value of the counter CNT. Reset to zero.

  Determination unit 340 receives actual current change length IBint, command current change length IRint, and counter CNT from integration unit 330. Further, the determination unit 340 receives the low voltage signal UV from the DC / DC converter 210. Based on such information, the determination unit 340 determines whether or not the CID is operating by the method described with reference to FIGS. 4 and 5 and sets the determination flag FLG. For example, when it is determined that the CID is operating, the determination flag FLG is set to ON, and when it is determined that the CID is not operating, the determination flag is set to OFF. Thereafter, determination unit 340 outputs set determination flag FLG to relay control unit 350.

  Relay control unit 350 receives determination flag FLG from determination unit 340. When the determination flag FLG is on, that is, when the CID is operating, the relay control unit 350 opens the SMR 115 by the control signal SE1.

  Drive control unit 360 receives required power PR and an abnormal signal ABN indicating that the system voltage sensor is abnormal. Drive control unit 360 generates control signals PWC and PWI for controlling converter 120 and inverters 130 and 135 based on required power PR. When the system voltage sensor is abnormal, drive control unit 360 blocks the gates of switching elements Q1 and Q2 in converter 120, and prohibits charging operation of power storage device 110 by the power generated by inverters 130 and 135. Only the discharging operation from the power storage device 110 is enabled.

  Instead of switching off the gates of switching elements Q1 and Q2 of converter 120, it is also possible to fix only switching element Q1 to the on state. In this case, there is an advantage that the regenerative operation is possible, but on the other hand, the power storage device 110 may be overcharged. Therefore, from the viewpoint of protection of the power storage device 110, it is preferable to perform gate cutoff.

  FIG. 7 is a flowchart for illustrating the details of the CID operation detection control process executed by ECU 300 in the first embodiment. The flowcharts described later with reference to FIGS. 7, 8, and 9 are realized by a program stored in advance in ECU 300 being called from the main routine and executed in a predetermined cycle. Alternatively, for some steps, processing can be realized by dedicated hardware (electronic circuit).

  Referring to FIGS. 1 and 7, ECU 300 determines whether or not both system voltage sensors (voltage sensors 180 and 185) are abnormal in step (hereinafter, step is abbreviated as S) 100.

  If at least one of the system voltage sensors is normal (NO in S100), the process proceeds to S115, and ECU 300 performs CID operation monitoring based on the value of the normal system voltage sensor while performing normal running. Run.

  If any of the system voltage sensors is abnormal (YES in S100), the process proceeds to S110, and ECU 300 shuts off switching elements Q1, Q2 of converter 120 and stops the regenerative operation.

  ECU 300 calculates command current IR based on required power PR and voltage VB of power storage device 110 (S120), and acquires actual current IB from current sensor 112 (S130).

  Thereafter, in S140, ECU 300 starts counter CNT and calculates change length IBint of actual current IB and change length IRint of command current IR.

  In S150, ECU 300 determines whether or not a predetermined monitoring time has elapsed based on the count value of counter CNT.

  If the predetermined monitoring time has not yet elapsed (NO in S150), the process is repeated from S120 to S140, and the counter is counted up, and the actual current change length IBint and the command current change length are increased. The IRint addition process is continued.

  If the predetermined monitoring time has elapsed (YES in S150), the process proceeds to S160, and as described with reference to FIG. 4, command current change length IRint is greater than or equal to threshold value α, and It is determined whether or not the current change length IBint is smaller than the threshold value β.

  If command current change length IRint is equal to or greater than threshold value α and actual current change length IBint is smaller than threshold value β (YES in S160), the process proceeds to S170, and ECU 300 operates CID. It is determined that Thereafter, the process proceeds to S180, and ECU 300 opens SMR 115.

  On the other hand, when command current change length IRint is smaller than threshold value α or actual current change length IBint is greater than or equal to threshold value β (NO in S160), ECU 300 may not operate CID. If it is determined that the value is low, the process proceeds to S175, the integrated values of the counter CNT, the command current change length IRint, and the actual current change length IBint are reset to initial values, and the process returns to the main routine.

  Although not shown, even when it is determined that the CID is activated, the integrated values of the counter CNT, the command current change length IRint, and the actual current change length IBint are reset to initial values.

  By performing control according to the above processing, it is possible to appropriately determine that the CID has been activated even when the system voltage sensor becomes abnormal.

[Embodiment 2]
In the first embodiment, the configuration in which the operation of the CID is detected using the change length of the actual current and the change length of the command current when the system voltage sensor becomes abnormal has been described.

  As described in the first embodiment, when the system voltage sensor becomes abnormal, when switching elements Q1 and Q2 in converter 120 in FIG. 1 are gated off, capacitor C1 has only power supplied from power storage device 110. Will be charged by.

  In such a state, when the CID operates, the power consumed by the motor generators 140 and 145 and the auxiliary device 200 is supplied by the power stored in the capacitor C1. However, since the CID is operating, the capacitor C1 is not charged by the power storage device 110. As a result, the voltage across the capacitor C1 (that is, the voltage VL) gradually decreases.

  At this time, in the configuration shown in FIG. 1, the input voltage of the DC / DC converter 210 included in the auxiliary device 200 is lowered. Therefore, when the voltage across the capacitor C1 falls below a predetermined voltage level, the DC / DC The converter 210 becomes inoperable, and the low voltage signal UV is output from the DC / DC converter 210.

  Therefore, in the second embodiment, it is determined that the voltage VL has been indirectly decreased by the low voltage signal UV from the DC / DC converter 210, thereby detecting that the CID is activated.

  FIG. 8 is a flowchart for explaining details of the CID operation detection control process executed by ECU 300 in the second embodiment.

  Referring to FIGS. 1 and 8, ECU 300 determines in S200 whether or not both system voltage sensors are abnormal.

  If at least one of the system voltage sensors is normal (NO in S200), the process proceeds to S250, and ECU 300 performs CID operation monitoring based on the value of the normal system voltage sensor while performing normal traveling. Run.

  If all of the system voltage sensors are abnormal (YES in S200), the process proceeds to S210, and ECU 300 gates switching elements Q1, Q2 of converter 120 and stops the regenerative operation.

  Next, in S220, ECU 300 determines whether or not low voltage signal UV from DC / DC converter 210 is on.

  If low voltage signal UV is off (NO in S220), ECU 300 determines that CID is not operating, and returns the process to the main routine.

  If low voltage signal UV is on (YES in S220), the process proceeds to S230, and ECU 300 determines that CID is activated. Thereafter, the process proceeds to S240, and ECU 300 opens SMR 115.

  By performing control according to the above processing, it is possible to appropriately determine that the CID has been activated even when the system voltage sensor becomes abnormal.

  In the above description, the configuration for detecting the operation of the CID using the low voltage signal UV from the DC / DC converter 210 has been described. However, if a signal similar to the low voltage signal UV can be output, the DC can be output. The CID may be detected based on a signal from another device different from the DC converter 210. For example, an air conditioner (not shown) connected to the power line PL1 and the ground line NL1 in parallel with the auxiliary device 200, equipment described in the auxiliary load 220, and the like may be included in this.

[Embodiment 3]
The third embodiment shows an example in which the first embodiment and the second embodiment described above are combined.

  Since the configuration of the second embodiment does not require the current change length calculation processing as in the first embodiment, the control logic can be a simple configuration. However, the input voltage of the DC / DC converter can be used. Since the operation of CID is not detected until a certain voltage VL drops to a predetermined voltage level, there is a possibility that the timing of detecting the operation of CID may be delayed.

  On the other hand, in the configuration of the first embodiment, a calculation process of the current change length is always required regardless of the level of the voltage VL, so that the calculation load becomes relatively high. For this reason, for example, when the voltage VL rapidly decreases in the power running state, the detection of the CID operation is delayed by the calculation of the current change length, and further, the CID operation detectability decreases due to variations in the current sensor. There is a fear.

  Therefore, when the voltage VL is reduced to the extent that the low voltage signal UV of the DC / DC converter is output by combining the first and second embodiments, the current change length calculation process is not performed. The operation of the CID can be determined immediately, and the CID can be determined using the current change length even before the voltage VL sufficiently decreases. This makes it possible to quickly detect the operation of the CID while reducing unnecessary arithmetic processing.

  FIG. 9 is a flowchart for illustrating details of the CID operation detection control process executed by ECU 300 in the third embodiment. FIG. 9 is obtained by adding step S111 to the flowchart described in FIG. 7 of the first embodiment. In FIG. 9, the description of the same steps as those in FIG. 7 will not be repeated.

  Referring to FIGS. 1 and 9, when both system voltage sensors become abnormal (YES in S100) and converter 120 is gate-cut (S110), ECU 300 causes DC / DC converter 210 in S111. It is determined whether the low voltage signal UV from is ON.

  When low voltage signal UV is off (NO in S111), ECU 300 causes ECU 300 to advance the process to S120, and, as described in the first embodiment, the actual current change length according to the processes of S120 to S160. CID operation detection using IBint and command current change length IRint is executed.

  On the other hand, when low voltage signal UV is on (YES in S111), the process proceeds to S170, and ECU 300 operates CID without calculating actual current change length IBint and command current change length IRint. It is determined that

  By performing control according to the above processing, it is possible to quickly detect the operation of the CID while reducing unnecessary arithmetic processing.

  “SMR115” in the present embodiment is an example of “switching device” in the present invention. The “DC / DC converter” in the present embodiment is an example of the “voltage converter” in the present invention.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

  100 vehicle, 110 power storage device, 111, 180, 185 voltage sensor, 112 current sensor, 115 SMR, 120 converter, 130, 135 inverter, 140, 145 motor generator, 150 power transmission gear, 160 engine, 170 driving wheel, 190 load Device, 200 auxiliary device, 210 DC / DC converter, 220 auxiliary load, 230 auxiliary battery, 300 ECU, 310 current detection unit, 320 command current calculation unit, 330 integration unit, 340 determination unit, 350 relay control unit, 360 Drive control unit, C1, C2 capacitor, CID current interrupt device, CL, CL1-CLn battery cell, D1, D2 diode, L1 reactor, NL1 ground line, PL1-PL3 power line, Q1, Q2 switching element.

Claims (14)

A power supply system for supplying driving power to a load device (190),
A power storage device (110) electrically connected to the load device (190);
A control device (300),
The power storage device (110) operates when the internal pressure of the power storage device (110) exceeds a specified value, and is configured to shut off the energization path of the power storage device (110). Including
The load device (190) includes a voltage detection unit (180, 185) for detecting a voltage applied to the load device (190), and responds to the failure of the voltage detection unit (180, 185). Then, the supply of power from the load device (190) to the power storage device (110) is stopped,
The control device (300) detects the presence or absence of operation of the shut-off device (CID) based on information from a signal output unit (112, 210) different from the voltage detection unit (180, 185). . The signal output unit includes a current detection unit (112) for detecting an actual current input to and output from the power storage device (110),
The control device (300) is based on the actual current detected by the current detection unit (112) and a command current to be input / output from the power storage device (110) determined from a required power based on a user operation. The power supply system of Claim 1 which detects the presence or absence of the action | operation of the said interruption | blocking apparatus (CID).   The control device (300) includes a change length obtained by integrating a magnitude of a change amount for each sampling cycle for the actual current and a change amount for each sampling cycle for the command current during a predetermined period. The power supply according to claim 2, wherein a change length obtained by integrating the magnitudes is calculated, and whether or not the interrupting device (CID) is activated is determined based on the change length of the actual current and the change length of the command current. system.   The control device (300) uses a first threshold value and a second threshold value that is greater than the first threshold value, so that the change length of the actual current is greater than the first threshold value. 4. The power supply system according to claim 3, wherein when the change length of the command current is small and greater than the second threshold value, it is determined that the interrupting device (CID) is activated. A switching device (115) for switching conduction and non-conduction between the power storage device (110) and the load device (190) on a path connecting the power storage device (110) and the load device (190). Provided,
The power supply system according to claim 4, wherein the control device (300) switches the switching device (115) to non-conduction when it is determined that the shut-off device (CID) is activated. The signal output unit includes an auxiliary device (200) connected to the power storage device (110) in parallel with the load device (190),
The auxiliary device (200) has a device (210) capable of outputting a voltage drop signal indicating that the input voltage has dropped in a state where driving is required,
The power supply system according to claim 1 or 2, wherein the control device (300) detects whether or not the shut-off device (CID) is activated based on the voltage drop signal from the device (210).   The power supply system according to claim 6, wherein the device includes a voltage conversion device (210) configured to step down power from the power storage device (110). A switching device (115) for switching conduction and non-conduction between the power storage device (110) and the load device (190) on a path connecting the power storage device (110) and the load device (190). Provided,
The power supply system according to claim 6, wherein the control device (300) switches the switching device (115) to non-conduction when it is determined that the shut-off device (CID) is activated. A vehicle,
A power storage device (110);
A load device (190) including a driving device configured to generate driving force of the vehicle (100) using electric power from the power storage device (110);
A control device (300),
The power storage device (110) operates when the internal pressure of the power storage device (110) exceeds a specified value, and is configured to shut off the energization path of the power storage device (110). Including
The load device (190) includes a voltage detection unit (180, 185) for detecting a voltage applied to the load device (190), and the voltage detection unit (180, 185) has failed. In response, the supply of power from the load device (190) to the power storage device (110) is stopped,
The said control apparatus (300) is a vehicle which detects the presence or absence of the action | operation of the said interruption | blocking apparatus (CID) based on the information from the signal output part (112,210) different from the said voltage detection part (180,185). The signal output unit includes a current detection unit (112) for detecting an actual current input to and output from the power storage device (110),
The control device (300) includes a change length obtained by integrating a magnitude of a change amount for each sampling period of the actual current detected by the current detection unit (112) during a predetermined period, and The change length obtained by integrating the magnitude of the change amount for each sampling period for the command current to be input / output from the power storage device (110) determined from the required power based on the user operation is calculated, and the change length of the actual current and the The vehicle according to claim 9, wherein the presence or absence of operation of the interrupting device (CID) is determined based on a change length of a command current. The signal output unit includes an auxiliary device (200) connected to the power storage device (110) in parallel with the load device (190),
The auxiliary device (200) can step down the power from the power storage device (110) and output a voltage drop signal indicating that the input voltage has dropped in a state where driving is required. Having a conversion device (210),
The vehicle according to claim 9 or 10, wherein the control device (300) detects the presence or absence of an operation of the interrupting device (CID) based on the voltage drop signal from the voltage conversion device (210). A control method of a power supply system including a power storage device (110) for supplying driving power to a load device (190),
The power storage device (110) operates when the internal pressure of the power storage device (110) exceeds a specified value, and is configured to shut off the energization path of the power storage device (110). Including
The load device (190) includes a voltage detector (180, 185) for detecting a voltage applied to the load device (190),
The control method is:
Detecting that the voltage detector (180, 185) has failed;
In response to the failure of the voltage detector (180, 185), stopping the supply of power from the load device (190) to the power storage device (110);
And a step of detecting whether or not the shut-off device (CID) is activated based on information from a signal output unit (112, 210) different from the voltage detection unit (180, 185). The signal output unit includes a current detection unit (112) for detecting an actual current input to and output from the power storage device (110),
The step of detecting whether or not the shut-off device (CID) is activated includes
Calculating a change length obtained by integrating a magnitude of a change amount for each sampling period for the actual current detected by the current detection unit (112) during a predetermined period;
During the predetermined period, a change length obtained by integrating the magnitude of the change amount for each sampling period for the command current to be input / output from the power storage device (110) determined from the required power based on the user operation is calculated. Steps,
The method for controlling the power supply system according to claim 12, further comprising: determining whether or not the interrupting device (CID) is activated based on a change length of the actual current and a change length of the command current. The signal output unit includes an auxiliary device (200) connected to the power storage device (110) in parallel with the load device (190),
The auxiliary device (200) can step down the power from the power storage device (110) and output a voltage drop signal indicating that the input voltage has dropped in a state where driving is required. Including a conversion device (210),
The step of detecting whether or not the shut-off device (CID) is activated includes
The method for controlling a power supply system according to claim 12 or 13, comprising a step of detecting whether or not the shut-off device (CID) is activated based on the voltage drop signal from the voltage converter (210).

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